Abstract
Despite the critical roles of plant species’ diversity and biological soil crusts (BSCs) in arid and semi-arid ecosystems, the restoration of the diversity of herbaceous species and BSCs are rarely discussed during the process of vegetation restoration of anthropogenically damaged areas in these regions. In this study, the herbaceous plant species composition, along with the BSCs coverage and thicknesses, was investigated at six different re-vegetation type sites, and the natural vegetation site of the Heidaigou open pit coal mine in China’s Inner Mongolia Autonomous Region was used as a reference. The highest total species richness (16), as well as the species richness (4.4), occurred in the Tree and Herbaceous vegetation type site. The species composition similarities between the restored sites and the reference site were shown to be very low, and ranged from 0.09 to 0.42. Also, among the restored sites, the similarities of the species were fairly high and similar, and ranged from 0.45 to 0.93. The density and height of the re-vegetated woody plants were significantly correlated with the indexes of the diversity of the species. The Shrub vegetation type site showed the greatest total coverage (80 %) of BSCs and algae crust coverage (48 %). The Shrub and Herbaceous type had the greatest thicknesses of BSCs, with as much as 3.06 mm observed, which was followed by 2.64 mm for the Shrub type. There was a significant correlation observed between the coverage of the total BSCs, and the total vegetation and herbaceous vegetation coverage, as well as between the algae crust coverage and the herbaceous vegetation coverage. It has been suggested that the re-vegetated dwarf woody plant species (such as shrubs and semi-shrubs) should be chosen for the optimal methods of the restoration of herbaceous species diversity at dumping sites, and these should be planted with low density. Furthermore, the effects of vegetation coverage on the colonization and development the BSCs should be considered in order to reconstruct the vegetation in disturbed environments, such as mine dumpsites in arid areas.
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References
Abdallah F, Chaieb M (2012) The influence of trees on nutrients, water, light availability and understorey vegetation in an arid environment. Appl Veg Sci 15:501–512
Bartels SF, Chen HY (2010) Is understory plant species diversity driven by resource quantity or resource heterogeneity? Ecology 91:1931–1938
Bekker RM, Verweij GL, Smith REN, Reine R, Bakker JP, Schneider S (1997) Soil seed banks in European grasslands: does land use affect regeneration perspectives? J Appl Ecol 34:1293–1310
Belnap J, Gillette DA (1998) Vulnerability of desert biological soil crusts to wind erosion: the influences of crust development, soil tex-ture, and disturbance. J Arid Environ 39:133–142
Belnap J, Lange OL (2003) Biological soil crusts: structure, function, and management. Springer, Berlin
Bowker MA (2007) Biological soil crust rehabilitation in theory and practice: an underexploited opportunity. Restor Ecol 15:13–23
Brom J, Nedbal V, Procházka J, Pecharová E (2012) Changes in vegetation cover, moisture properties and surface temperature of a brown coal dump from 1984 to 2009 using satellite data analysis. Ecol Eng 43:45–52
Bullock JM, Aronson J, Newton AC, Pywell RF, Rey-Benayas JM (2011) Restoration of ecosystem services and biodiversity: conflicts and opportunities. Trends Ecol Evol 26:541–549
Butchart SH, Walpole M, Collen B, van Strien A, Scharlemann JP, Almond RE et al (2010) Global biodiversity: indicators of recent declines. Science 328:1164–1168
Castro J, Zamora R, Hódar JA, Gómez JM (2004) Seedling establishment of a boreal tree species (Pinus sylvestris) at its southernmost distribution limit: consequences of being in a marginal Mediterranean habitat. J Ecol 92:266–277
Editorial Committee of the Flora of China (1998) Flora of China. Science Press, Beijing (in Chinese)
Eldridge DJ, Zaady E, Shachack M (2002) Microphytic crusts, shrub patches, and water harvesting in the Negev desert: the Shikimsystem. Landsc Ecol 17:587–597
Eriksson O, Ehrlén J (2001) Landscape fragmentation and viability of plant populations. In: Silvertown J, Antonovics J (eds) Integrating ecology and evolution in a spatial context. Blackwell, Oxford
Filcheva E, Noustorova M, Gentcheva-Kostadinova S, Haigh MJ (2000) Organic accumulation and microbial action in surface coal-mine spoils, Pernik, Bulgaria. Ecol Eng 15:1–15
Guo YR, Zhao HL, Zuo XA, Drake S, Zhao XY (2008) Biological soil crust development and its surface soil properties in the process of dune stabilization, Inner Mongolia, China. Environ Geol 54:653–662
He F, Yin J (2010) Environmental effect of land cover change: a case study of coal mining areas in Beijing, China. In: 18th International Conference on Geoinfor-matics, Beijing, China. Biotropica 40: 543-549
Jiang W, Cheng Y, Yang X, Yang S (2013) Chinese Loess Plateau vegetation since the last glacial maximum and its implications for vegetation restoration. J Appl Ecol 50:440–448
Li XR (2005) Influence of variation of soil spatial heterogeneity on vegetation restoration. Sci China, Ser D 48:2020–2031
Li XR (2012) Eco-hydrology of biological soil crusts in desert regions of China. Higher Education Press, Beijing (in Chinese)
Li XR, He MZ, Zerbe S, Li XJ, Liu LC (2010) Micro-geomorphology determines community structure of biological soil crusts at small scales. Earth Surf Proc Land 35:932–940
Li XR, Zhang P, Su YG, Jia RL (2012) Carbon fixation by biological soil crusts following revegetation of sand dunes in arid desert regions of China: a four-year field study. Catena 97:119–126
Lindborg R, Eriksson O (2004) Historical landscape connectivity affects present plant species diversity. Ecology 85:1840–1845
Ludwig F, de Kroon H, Berendse F, Prins HH (2004) The influence of savanna trees on nutrient, water and light availability and the understorey vegetation. Plant Ecol 170:93–105
Maestre FT, Valladares F, Reynolds JF (2005) Is the change of plant –plant interactions with abiotic stress predict-able? A meta-analysis of field results in arid environments. J Ecol 93:748–757
McPherson RA (2007) A review of vegetation-atmosphere interactions and their influences on mesoscale phenomena. Prog Phys Geog 31:261–285
Ochoa-Hueso R, Hernandez RR, Pueyo JJ, Manrique E (2011) Spatial distribution and physiology of biological soil crusts from semi-arid central Spain are related to soil chemistry and shrub cover. Soil Biol Biochem 43:1894–1901
Parrotta JA, Turnbull JW, Jones N (1997) Catalyzing native forest regeneration on degraded tropical lands. For Ecol Manag 99:1–7
Ponzetti JM, McCune B, Pyke DA (2007) Biotic soil crusts in relation to topography, cheatgrass and fire in the Columbia Basin, Washington. Bryologist 110:706–722
Schaller N (1993) The concept of agricultural sustainability. Agric Ecosyst Environ 46:89–97
Schlensog M, Green TA, Schroeter B (2013) Life form and water source interact to determine active time and environment in cryptogams: an example from the maritime Antarctic. Oecologia 173:59–72
Serpe MD, Orm JM, Barkes T, Rosentreter R (2006) Germination and seed water status of four grasses on moss-dominated bio-logical soil crusts from arid lands. Plant Ecol 185:163–178
Singh AN, Raghubanshi AS, Singh JS (2002) Plantations as a tool for mine spoil restoration. Curr Sci India 82:1436–1441
Soliveres S, Monerris J, Cortina J (2012) Irrigation, organic fertilization and species successional stage modulate the response of woody seedlings to herbaceous competition in a semi-arid quarry restoration. Appl Veg Sci 15:175–186
Strykstra RJ, Bekker RM, Bakker JP (1998) Assessment of dispersal availability: its practical use in restoration management. Acta Bot Neerl 47:57–70
Wang J, Jiao Z, Bai Z (2013) Changes in carbon sink value based on RS and GIS in the Heidaigou opencast coal mine. Environ Earth Sci 69:1–9
Zaady E, Arbel S, Barkai D, Sarig S (2013) Long-term impact of agricultural practices on biological soil crusts and their hydrological processes in a semiarid landscape. J Arid Environ 90:5–11
Zhao HL, Zhou RL, Su YZ, Zhang H, Zhao LY, Drake S (2007) Shrub facilitation of desert land restoration in the Horqin Sand Land of Inner Mongolia. Ecol Eng 31:1–8
Zhao HL, Guo YR, Zhou RL, Drake S (2010) Biological soil crust and surface soil properties in different vegetation types of Horqin Sand Land, China. Catena 82:70–76
Zhao Y, Li XR, Zhang P, Hu YG, Huang L (2015) Effects of vegetation reclamation on temperature and humidity properties of a dumpsite: a case study in the open pit coal mine of Heidaigou. Arid Land Res Manag 29:375–381
Acknowledgments
This research study was sponsored by the CAS Action-Plan for Western Development (KZCX2-XB3-13-03) and the National Natural Science Foundation of China (41501270) and the Foundation for Excellent Youth Scholars of CAREERI, CAS.
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Zhao, Y., Zhang, P., Hu, Y. et al. Effects of Re-vegetation on Herbaceous Species Composition and Biological Soil Crusts Development in a Coal Mine Dumping Site. Environmental Management 57, 298–307 (2016). https://doi.org/10.1007/s00267-015-0607-9
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DOI: https://doi.org/10.1007/s00267-015-0607-9